| |
| |
| |
| |
|
|
| import io |
| import logging |
| import os |
| import pickle |
| import random |
| import socket |
| import struct |
| import subprocess |
| import warnings |
| from argparse import Namespace |
| from collections import OrderedDict |
| from dataclasses import dataclass |
| from typing import Any, Dict, List, Mapping, Optional |
|
|
| import torch |
| import torch.distributed as dist |
| from fairseq.dataclass.configs import DistributedTrainingConfig, FairseqConfig |
| from omegaconf import open_dict |
|
|
| try: |
| import torch_xla.core.xla_model as xm |
| except ImportError: |
| xm = None |
|
|
|
|
| |
| |
| _USE_MEGATRON = False |
|
|
| |
| _USE_XLA = False |
|
|
|
|
| logger = logging.getLogger(__name__) |
|
|
|
|
| def is_master(cfg: DistributedTrainingConfig): |
| return cfg.distributed_rank == 0 |
|
|
|
|
| def infer_init_method(cfg: DistributedTrainingConfig, force_distributed=False): |
| if cfg.distributed_init_method is not None or cfg.tpu: |
| return |
|
|
| num_pipelines_per_node = None |
| if cfg.pipeline_model_parallel: |
| num_pipeline_devices, num_pipelines_per_node = _pipeline_parallel_pre_init(cfg) |
|
|
| if all( |
| key in os.environ |
| for key in ["MASTER_ADDR", "MASTER_PORT", "WORLD_SIZE", "RANK"] |
| ): |
| |
| _infer_torch_distributed_launch_init(cfg) |
| elif cfg.distributed_port > 0: |
| |
| _infer_slurm_init(cfg, num_pipelines_per_node) |
| elif cfg.distributed_world_size > 1 or force_distributed: |
| |
| _infer_single_node_init(cfg) |
|
|
| if cfg.pipeline_model_parallel: |
| _pipeline_parallel_post_init(cfg, num_pipeline_devices, num_pipelines_per_node) |
| elif not cfg.distributed_no_spawn: |
| with open_dict(cfg): |
| cfg.distributed_num_procs = min( |
| torch.cuda.device_count(), cfg.distributed_world_size |
| ) |
|
|
|
|
| def _infer_torch_distributed_launch_init(cfg: DistributedTrainingConfig): |
| cfg.distributed_init_method = "env://" |
| cfg.distributed_world_size = int(os.environ["WORLD_SIZE"]) |
| cfg.distributed_rank = int(os.environ["RANK"]) |
| |
| cfg.distributed_no_spawn = True |
|
|
|
|
| def _infer_slurm_init(cfg: DistributedTrainingConfig, num_pipelines_per_node): |
| node_list = os.environ.get("SLURM_STEP_NODELIST") |
| if node_list is None: |
| node_list = os.environ.get("SLURM_JOB_NODELIST") |
| if node_list is not None: |
| try: |
| hostnames = subprocess.check_output( |
| ["scontrol", "show", "hostnames", node_list] |
| ) |
| cfg.distributed_init_method = "tcp://{host}:{port}".format( |
| host=hostnames.split()[0].decode("utf-8"), |
| port=cfg.distributed_port, |
| ) |
| nnodes = int(os.environ.get("SLURM_NNODES")) |
| ntasks_per_node = os.environ.get("SLURM_NTASKS_PER_NODE") |
| if ntasks_per_node is not None: |
| ntasks_per_node = int(ntasks_per_node) |
| else: |
| ntasks = int(os.environ.get("SLURM_NTASKS")) |
| nnodes = int(os.environ.get("SLURM_NNODES")) |
| assert ntasks % nnodes == 0 |
| ntasks_per_node = int(ntasks / nnodes) |
| if ntasks_per_node == 1: |
| gpus_per_node = torch.cuda.device_count() |
| node_id = int(os.environ.get("SLURM_NODEID")) |
| cfg.distributed_rank = node_id * gpus_per_node |
| cfg.distributed_world_size = nnodes * gpus_per_node |
| elif cfg.pipeline_model_parallel: |
| assert ntasks_per_node == num_pipelines_per_node, ( |
| "SLURM --ntasks-per-node must match number of pipelines per " |
| "node (={})".format(num_pipelines_per_node) |
| ) |
| cfg.distributed_no_spawn = True |
| |
| |
| |
| node_id = int(os.environ.get("SLURM_NODEID")) |
| local_id = int(os.environ.get("SLURM_LOCALID")) |
| cfg.distributed_rank = node_id * num_pipelines_per_node + local_id |
| |
| |
| cfg.device_id = local_id |
| |
| |
| cfg.distributed_world_size = nnodes * num_pipelines_per_node |
| else: |
| assert ntasks_per_node == cfg.distributed_world_size // nnodes |
| cfg.distributed_no_spawn = True |
| cfg.distributed_rank = int(os.environ.get("SLURM_PROCID")) |
| cfg.device_id = int(os.environ.get("SLURM_LOCALID")) |
| except subprocess.CalledProcessError as e: |
| raise e |
| except FileNotFoundError: |
| pass |
|
|
|
|
| def _infer_single_node_init(cfg: DistributedTrainingConfig): |
| assert ( |
| cfg.distributed_world_size <= torch.cuda.device_count() |
| ), f"world size is {cfg.distributed_world_size} but have {torch.cuda.device_count()} available devices" |
| port = random.randint(10000, 20000) |
| cfg.distributed_init_method = "tcp://localhost:{port}".format(port=port) |
|
|
|
|
| def _pipeline_parallel_pre_init(cfg: DistributedTrainingConfig): |
| from fairseq import utils |
|
|
| balance_exists = ( |
| cfg.pipeline_balance is not None |
| or cfg.pipeline_encoder_balance is not None |
| or cfg.pipeline_decoder_balance is not None |
| ) |
| devices_exist = ( |
| cfg.pipeline_devices is not None |
| or cfg.pipeline_encoder_devices is not None |
| or cfg.pipeline_decoder_devices is not None |
| ) |
| if not balance_exists: |
| raise ValueError( |
| "--pipeline-balance is currently required for pipeline model parallelism" |
| ) |
| if not devices_exist: |
| raise ValueError( |
| "--pipeline-devices is currently required for pipeline model parallelism" |
| ) |
|
|
| cfg.pipeline_balance = utils.eval_str_list(cfg.pipeline_balance, type=int) |
| if cfg.pipeline_devices is not None: |
| cfg.pipeline_devices = utils.eval_str_list(cfg.pipeline_devices, type=int) |
| num_pipeline_devices = len(set(cfg.pipeline_devices)) |
| else: |
| cfg.pipeline_encoder_devices = utils.eval_str_list( |
| cfg.pipeline_encoder_devices, type=int |
| ) |
| cfg.pipeline_decoder_devices = utils.eval_str_list( |
| cfg.pipeline_decoder_devices, type=int |
| ) |
| num_pipeline_devices = len( |
| set(cfg.pipeline_encoder_devices + cfg.pipeline_decoder_devices) |
| ) |
| gpus_per_node = torch.cuda.device_count() |
| assert ( |
| gpus_per_node >= num_pipeline_devices |
| and gpus_per_node % num_pipeline_devices == 0 |
| ), ( |
| "the number of unique device IDs in --pipeline-devices must evenly divide " |
| "the number of GPUs per node (multi-node pipelining is not yet supported)" |
| ) |
| num_pipelines_per_node = gpus_per_node // num_pipeline_devices |
| return num_pipeline_devices, num_pipelines_per_node |
|
|
|
|
| def _pipeline_parallel_post_init( |
| cfg: DistributedTrainingConfig, num_pipeline_devices, num_pipelines_per_node |
| ): |
| if not cfg.distributed_no_spawn: |
| |
| |
| |
| assert cfg.distributed_world_size % num_pipeline_devices == 0 |
| cfg.distributed_world_size = ( |
| cfg.distributed_world_size // num_pipeline_devices |
| ) |
| |
| |
| |
| gpus_per_node = torch.cuda.device_count() |
| assert cfg.distributed_rank % gpus_per_node == 0 |
| assert cfg.distributed_rank % num_pipeline_devices == 0 |
|
|
| with open_dict(cfg): |
| cfg.distributed_rank = cfg.distributed_rank // num_pipeline_devices |
| |
| cfg.distributed_num_procs = num_pipelines_per_node |
|
|
| |
| |
| cfg.device_id *= num_pipeline_devices |
|
|
| if cfg.device_id > 0: |
| |
| |
| logger.debug( |
| "setting CUDA device={} on rank {}".format( |
| cfg.device_id, cfg.distributed_rank |
| ) |
| ) |
| torch.cuda.set_device(cfg.device_id) |
| with open_dict(cfg): |
| cfg.pipeline_devices = [cfg.device_id + d for d in cfg.pipeline_devices] |
| logger.info( |
| "setting pipeline_devices={} on rank {}".format( |
| cfg.pipeline_devices, cfg.distributed_rank |
| ) |
| ) |
|
|
|
|
| def distributed_init(cfg: FairseqConfig): |
| if isinstance(cfg, Namespace): |
| from fairseq.dataclass.utils import convert_namespace_to_omegaconf |
|
|
| cfg = convert_namespace_to_omegaconf(cfg) |
|
|
| if not cfg.common.tpu: |
| if torch.distributed.is_available() and torch.distributed.is_initialized(): |
| warnings.warn( |
| "Distributed is already initialized, cannot initialize twice!" |
| ) |
| else: |
| logger.info( |
| "distributed init (rank {}): {}".format( |
| cfg.distributed_training.distributed_rank, |
| cfg.distributed_training.distributed_init_method, |
| ) |
| ) |
| dist.init_process_group( |
| backend=cfg.distributed_training.distributed_backend, |
| init_method=cfg.distributed_training.distributed_init_method, |
| world_size=cfg.distributed_training.distributed_world_size, |
| rank=cfg.distributed_training.distributed_rank, |
| ) |
| logger.info( |
| "initialized host {} as rank {}".format( |
| socket.gethostname(), |
| cfg.distributed_training.distributed_rank, |
| ) |
| ) |
|
|
| |
| if torch.cuda.is_available(): |
| dist.all_reduce(torch.zeros(1).cuda()) |
|
|
| cfg.distributed_training.distributed_rank = torch.distributed.get_rank() |
| else: |
| assert xm.xrt_world_size() == cfg.distributed_training.distributed_world_size |
| global _USE_XLA |
| _USE_XLA = True |
| cfg.distributed_training.device_id = xm.get_local_ordinal() |
| cfg.distributed_training.distributed_rank = xm.get_ordinal() |
| xm.rendezvous("distributed_init") |
|
|
| if is_master(cfg.distributed_training): |
| logging.getLogger().setLevel(logging.INFO) |
| else: |
| logging.getLogger().setLevel(logging.WARNING) |
|
|
| if cfg.common.model_parallel_size > 1: |
| try: |
| from fairseq.model_parallel.megatron.mpu import ( |
| initialize_model_parallel, |
| model_parallel_cuda_manual_seed, |
| ) |
| except ImportError: |
| raise ImportError( |
| "\n\nPlease install the megatron submodule:" |
| "\n\n git submodule update --init " |
| "fairseq/model_parallel/megatron" |
| ) |
| global _USE_MEGATRON |
| _USE_MEGATRON = True |
| initialize_model_parallel(cfg.common.model_parallel_size) |
| model_parallel_cuda_manual_seed(cfg.common.seed) |
| model_part_number = get_model_parallel_rank() |
| cfg.checkpoint.checkpoint_suffix += "-model_part-{0}".format(model_part_number) |
|
|
| if hasattr(cfg, "model") and getattr(cfg.model, "base_layers", 0) > 0: |
| cfg.checkpoint.checkpoint_suffix = f"-rank-{cfg.distributed_training.distributed_rank}" |
|
|
| return cfg.distributed_training.distributed_rank |
|
|
|
|
| def distributed_main(i, main, cfg: FairseqConfig, kwargs): |
| cfg.distributed_training.device_id = i |
| if torch.cuda.is_available() and not cfg.common.cpu and not cfg.common.tpu: |
| torch.cuda.set_device(cfg.distributed_training.device_id) |
| if cfg.distributed_training.distributed_rank is None: |
| cfg.distributed_training.distributed_rank = kwargs.pop("start_rank", 0) + i |
|
|
| cfg.distributed_training.distributed_rank = distributed_init(cfg) |
|
|
| after_distributed_init_fn = kwargs.pop("after_distributed_init_fn", None) |
| if after_distributed_init_fn: |
| cfg = after_distributed_init_fn(cfg) |
|
|
| main(cfg, **kwargs) |
|
|
| if torch.distributed.is_initialized(): |
| torch.distributed.barrier(get_global_group()) |
|
|
|
|
| def call_main(cfg: FairseqConfig, main, **kwargs): |
| if cfg.distributed_training.distributed_init_method is None: |
| infer_init_method(cfg.distributed_training) |
|
|
| if cfg.distributed_training.distributed_init_method is not None: |
| |
| if not cfg.distributed_training.distributed_no_spawn: |
| start_rank = cfg.distributed_training.distributed_rank |
| cfg.distributed_training.distributed_rank = None |
| kwargs["start_rank"] = start_rank |
| torch.multiprocessing.spawn( |
| fn=distributed_main, |
| args=(main, cfg, kwargs), |
| nprocs=min( |
| torch.cuda.device_count(), |
| cfg.distributed_training.distributed_world_size, |
| ), |
| join=True, |
| ) |
| else: |
| distributed_main(cfg.distributed_training.device_id, main, cfg, kwargs) |
| elif cfg.common.tpu and cfg.distributed_training.distributed_world_size > 1: |
| import torch_xla.distributed.xla_multiprocessing as xmp |
|
|
| torch.multiprocessing.set_sharing_strategy("file_system") |
| xmp.spawn( |
| fn=distributed_main, |
| args=(main, cfg, kwargs), |
| |
| |
| |
| nprocs=min(cfg.distributed_training.distributed_world_size, 8), |
| ) |
| else: |
| |
| main(cfg, **kwargs) |
|
|
|
|
| def use_xla(): |
| global _USE_XLA |
| return _USE_XLA |
|
|
|
|
| def new_groups(grouped_ranks: List[List[int]]): |
| if use_xla(): |
| return ("tpu", grouped_ranks) |
| else: |
| groups = [dist.new_group(g) for g in grouped_ranks] |
| my_group_idx = _find_my_group_index(grouped_ranks) |
| return groups[my_group_idx] |
|
|
|
|
| def _find_my_group_index(grouped_ranks): |
| my_rank = get_global_rank() |
| for i, group in enumerate(grouped_ranks): |
| if my_rank in group: |
| return i |
| raise RuntimeError |
|
|
|
|
| def _find_my_group(grouped_ranks): |
| index = _find_my_group_index(grouped_ranks) |
| return grouped_ranks[index] |
|
|
|
|
| def get_rank(group): |
| if use_xla(): |
| assert group[0] == "tpu" |
| my_group = _find_my_group(group[1]) |
| return my_group.index(get_global_rank()) |
| else: |
| return dist.get_rank(group=group) |
|
|
|
|
| def get_world_size(group): |
| if use_xla(): |
| assert group[0] == "tpu" |
| my_group = _find_my_group(group[1]) |
| return len(my_group) |
| elif torch.distributed.is_initialized(): |
| return dist.get_world_size(group=group) |
| else: |
| return 1 |
|
|
|
|
| def get_global_group(): |
| if use_xla(): |
| return new_groups([list(range(get_global_world_size()))]) |
| elif torch.distributed.is_initialized(): |
| if not hasattr(get_global_group, "_global_group"): |
| |
| |
| get_global_group._global_group = dist.new_group() |
| return get_global_group._global_group |
| else: |
| return None |
|
|
|
|
| def get_global_rank(): |
| if use_xla(): |
| return xm.get_ordinal() |
| elif torch.distributed.is_initialized(): |
| return torch.distributed.get_rank() |
| else: |
| return 0 |
|
|
|
|
| def get_global_world_size(): |
| if use_xla(): |
| return xm.xrt_world_size() |
| elif torch.distributed.is_initialized(): |
| return torch.distributed.get_world_size() |
| else: |
| return 1 |
|
|
|
|
| def get_data_parallel_group(): |
| """Get the data parallel group the caller rank belongs to.""" |
| global _USE_MEGATRON |
| if _USE_MEGATRON: |
| from fairseq.model_parallel.megatron import mpu |
|
|
| return mpu.get_data_parallel_group() |
| else: |
| return get_global_group() |
|
|
|
|
| def get_data_parallel_rank(): |
| """Return my rank for the data parallel group.""" |
| return get_rank(get_data_parallel_group()) |
|
|
|
|
| def get_data_parallel_world_size(): |
| """Return world size for the data parallel group.""" |
| return get_world_size(get_data_parallel_group()) |
|
|
|
|
| def get_model_parallel_group(): |
| global _USE_MEGATRON |
| if _USE_MEGATRON: |
| from fairseq.model_parallel.megatron import mpu |
|
|
| return mpu.get_model_parallel_group() |
| else: |
| return None |
|
|
|
|
| def get_model_parallel_rank(): |
| """Return my rank for the model parallel group.""" |
| return get_rank(get_model_parallel_group()) |
|
|
|
|
| def get_model_parallel_world_size(): |
| """Return world size for the model parallel group.""" |
| return get_world_size(get_model_parallel_group()) |
|
|
|
|
| def all_reduce(tensor, group, op="sum"): |
| if use_xla(): |
| assert isinstance(group, tuple) and group[0] == "tpu" |
| tensor = [tensor] |
| return xm.all_reduce(op, tensor, groups=group[1])[0] |
| else: |
| if op == "sum": |
| op = dist.ReduceOp.SUM |
| elif op == "max": |
| op = dist.ReduceOp.MAX |
| else: |
| raise NotImplementedError |
| dist.all_reduce(tensor, op=op, group=group) |
| return tensor |
|
|
|
|
| def broadcast(tensor, src, group): |
| if use_xla(): |
| |
| if get_rank(group) != src: |
| tensor.zero_() |
| all_reduce(tensor, group) |
| else: |
| dist.broadcast(tensor, src=src, group=group) |
|
|
|
|
| def all_to_all(tensor, group): |
| """Perform an all-to-all operation on a 1D Tensor.""" |
| assert tensor.dim() == 1 |
| split_count = get_world_size(group=group) |
| assert tensor.numel() % split_count == 0 |
| if use_xla(): |
| assert isinstance(group, tuple) and group[0] == "tpu" |
| return xm.all_to_all( |
| tensor, |
| split_dimension=0, |
| concat_dimension=0, |
| split_count=split_count, |
| groups=group[1], |
| ) |
| else: |
| output = torch.zeros_like(tensor) |
| dist.all_to_all_single(output, tensor, group=group) |
| return output |
|
|
|
|
| def all_gather(tensor, group, return_tensor=False): |
| """Perform an all-gather operation.""" |
| if use_xla(): |
| result = xm.all_gather(tensor, groups=group[1]) |
| world_size = get_world_size(group=group) |
| result = result.view(world_size, *tensor.size()) |
| if return_tensor: |
| return result |
| else: |
| return [result[i] for i in range(world_size)] |
| else: |
| world_size = get_world_size(group=group) |
| rank = get_rank(group=group) |
| tensor_list = [ |
| tensor if i == rank else torch.empty_like(tensor) for i in range(world_size) |
| ] |
| dist.all_gather(tensor_list, tensor, group=group) |
| if return_tensor: |
| return torch.stack(tensor_list, dim=0) |
| else: |
| return tensor_list |
|
|
|
|
| def all_gather_list(data, group=None, max_size=16384): |
| """Gathers arbitrary data from all nodes into a list. |
| |
| Similar to :func:`~torch.distributed.all_gather` but for arbitrary Python |
| data. Note that *data* must be picklable and any CUDA tensors will be moved |
| to CPU and returned on CPU as well. |
| |
| Args: |
| data (Any): data from the local worker to be gathered on other workers |
| group: group of the collective |
| max_size (int, optional): maximum size of the data to be gathered |
| across workers |
| """ |
| from fairseq import utils |
|
|
| if group is None: |
| group = get_global_group() |
| rank = get_rank(group=group) |
| world_size = get_world_size(group=group) |
|
|
| buffer_size = max_size * world_size |
| if ( |
| not hasattr(all_gather_list, "_buffer") |
| or all_gather_list._buffer.numel() < buffer_size |
| ): |
| all_gather_list._buffer = torch.cuda.ByteTensor(buffer_size) |
| all_gather_list._cpu_buffer = torch.ByteTensor(max_size).pin_memory() |
| buffer = all_gather_list._buffer |
| buffer.zero_() |
| cpu_buffer = all_gather_list._cpu_buffer |
|
|
| data = utils.move_to_cpu(data) |
| enc = pickle.dumps(data) |
| enc_size = len(enc) |
| header_size = 4 |
| size = header_size + enc_size |
| if size > max_size: |
| raise ValueError( |
| "encoded data size ({}) exceeds max_size ({})".format(size, max_size) |
| ) |
|
|
| header = struct.pack(">I", enc_size) |
| cpu_buffer[:size] = torch.ByteTensor(list(header + enc)) |
| start = rank * max_size |
| buffer[start : start + size].copy_(cpu_buffer[:size]) |
|
|
| all_reduce(buffer, group=group) |
|
|
| buffer = buffer.cpu() |
| try: |
| result = [] |
| for i in range(world_size): |
| out_buffer = buffer[i * max_size : (i + 1) * max_size] |
| (enc_size,) = struct.unpack(">I", bytes(out_buffer[:header_size].tolist())) |
| if enc_size > 0: |
| result.append( |
| pickle.loads( |
| bytes(out_buffer[header_size : header_size + enc_size].tolist()) |
| ) |
| ) |
| return result |
| except pickle.UnpicklingError: |
| raise Exception( |
| "Unable to unpickle data from other workers. all_gather_list requires all " |
| "workers to enter the function together, so this error usually indicates " |
| "that the workers have fallen out of sync somehow. Workers can fall out of " |
| "sync if one of them runs out of memory, or if there are other conditions " |
| "in your training script that can cause one worker to finish an epoch " |
| "while other workers are still iterating over their portions of the data. " |
| "Try rerunning with --ddp-backend=legacy_ddp and see if that helps." |
| ) |
|
|
|
|
| def all_reduce_dict(data: Mapping[str, Any], device, group) -> Dict[str, Any]: |
| """ |
| AllReduce a dictionary of values across workers. We separately |
| reduce items that are already on the device and items on CPU for |
| better performance. |
| |
| Args: |
| data (Mapping[str, Any]): dictionary of data to all-reduce, but |
| cannot be a nested dictionary |
| device (torch.device): device for the reduction |
| group: group of the collective |
| """ |
| data_keys = list(data.keys()) |
|
|
| |
| |
| cpu_data = OrderedDict() |
| device_data = OrderedDict() |
| for k in data_keys: |
| t = data[k] |
| if not torch.is_tensor(t): |
| cpu_data[k] = torch.tensor(t, dtype=torch.double) |
| elif t.device.type != device.type: |
| cpu_data[k] = t.to(dtype=torch.double) |
| else: |
| device_data[k] = t.to(dtype=torch.double) |
|
|
| def _all_reduce_dict(data: OrderedDict): |
| if len(data) == 0: |
| return data |
| buf = torch.cat([t.view(-1) for t in data.values()]).to(device=device) |
| all_reduce(buf, group=group) |
| split_buf = torch.split(buf, [t.numel() for t in data.values()]) |
| reduced_data = [t.view_as(orig) for t, orig in zip(split_buf, data.values())] |
| return OrderedDict(zip(data.keys(), reduced_data)) |
|
|
| cpu_data = _all_reduce_dict(cpu_data) |
| device_data = _all_reduce_dict(device_data) |
|
|
| def get_from_stack(key): |
| if key in cpu_data: |
| return cpu_data[key] |
| elif key in device_data: |
| return device_data[key] |
| raise KeyError |
|
|
| return OrderedDict([(key, get_from_stack(key)) for key in data_keys]) |
|
|
|
|
| def broadcast_tensors( |
| tensors: Optional[List[torch.Tensor]], |
| src_rank: int, |
| group: object, |
| dist_device: Optional[torch.device] = None, |
| ) -> List[torch.Tensor]: |
| """ |
| Broadcasts a list of tensors without other (non-src) ranks needing to know |
| the dtypes/shapes of the tensors. |
| """ |
| if dist_device is None: |
| if torch.distributed.get_backend(group) == "nccl": |
| dist_device = torch.device("cuda") |
| else: |
| dist_device = torch.device("cpu") |
|
|
| |
| is_src_rank = (get_rank(group) == src_rank) |
| if is_src_rank: |
| metadata = [ |
| {"size": t.size(), "dtype": t.dtype, "device": t.device} for t in tensors |
| ] |
| metadata = _broadcast_object_slow(metadata, src_rank, group, dist_device) |
| else: |
| metadata = _broadcast_object_slow(None, src_rank, group, dist_device) |
|
|
| out_tensors = [] |
| for i, meta in enumerate(metadata): |
| if is_src_rank: |
| tensor = tensors[i] |
| broadcast(tensors[i].to(dist_device), src=src_rank, group=group) |
| else: |
| tensor = torch.zeros( |
| [meta["size"].numel()], dtype=meta["dtype"], device=dist_device |
| ) |
| broadcast(tensor, src=src_rank, group=group) |
| tensor = tensor.view(meta["size"]).to(meta["device"]) |
| out_tensors.append(tensor) |
| return out_tensors |
|
|
|
|
| def broadcast_object( |
| obj: Any, |
| src_rank: int, |
| group: object, |
| dist_device: Optional[torch.device] = None, |
| ) -> Any: |
| """Broadcast an arbitrary Python object to other workers.""" |
| if dist_device is None: |
| if torch.distributed.get_backend(group) == "nccl": |
| dist_device = torch.device("cuda") |
| else: |
| dist_device = torch.device("cpu") |
|
|
| if get_rank(group) == src_rank: |
| |
| |
| tensors = [] |
| obj = _split_tensors_from_obj(obj, tensors) |
| obj = _broadcast_object_slow(obj, src_rank, group, dist_device) |
| tensors = broadcast_tensors(tensors, src_rank, group, dist_device) |
| else: |
| obj = _broadcast_object_slow(None, src_rank, group, dist_device) |
| tensors = broadcast_tensors(None, src_rank, group, dist_device) |
| return _put_tensors_in_obj(obj, tensors) |
|
|
|
|
| def _broadcast_object_slow( |
| obj: Any, src_rank: int, group: object, dist_device: torch.device, |
| ) -> Any: |
| if get_rank(group) == src_rank: |
| |
| buffer = io.BytesIO() |
| torch.save(obj, buffer) |
| buffer = torch.ByteTensor(buffer.getbuffer()).to(dist_device) |
| length = torch.LongTensor([len(buffer)]).to(dist_device) |
| broadcast(length, src=src_rank, group=group) |
| broadcast(buffer, src=src_rank, group=group) |
| else: |
| |
| length = torch.LongTensor([0]).to(dist_device) |
| broadcast(length, src=src_rank, group=group) |
| buffer = torch.ByteTensor(int(length.item())).to(dist_device) |
| broadcast(buffer, src=src_rank, group=group) |
| buffer = io.BytesIO(buffer.cpu().numpy()) |
| obj = torch.load(buffer, map_location="cpu") |
| return obj |
|
|
|
|
| @dataclass(frozen=True) |
| class _TensorPlaceholder: |
| index: int |
|
|
|
|
| def _split_tensors_from_obj(obj: Any, tensors: List[torch.Tensor]) -> Any: |
| if torch.is_tensor(obj): |
| placeholder = _TensorPlaceholder(index=len(tensors)) |
| tensors.append(obj) |
| return placeholder |
| elif isinstance(obj, dict): |
| return {k: _split_tensors_from_obj(v, tensors) for k, v in obj.items()} |
| elif isinstance(obj, list): |
| return [_split_tensors_from_obj(v, tensors) for v in obj] |
| elif isinstance(obj, tuple): |
| return tuple(_split_tensors_from_obj(v, tensors) for v in obj) |
| elif isinstance(obj, set): |
| return {_split_tensors_from_obj(v, tensors) for v in obj} |
| else: |
| return obj |
|
|
|
|
| def _put_tensors_in_obj(obj: Any, tensors: List[torch.Tensor]) -> Any: |
| if isinstance(obj, _TensorPlaceholder): |
| return tensors[obj.index] |
| elif isinstance(obj, dict): |
| return {k: _put_tensors_in_obj(v, tensors) for k, v in obj.items()} |
| elif isinstance(obj, list): |
| return [_put_tensors_in_obj(v, tensors) for v in obj] |
| elif isinstance(obj, tuple): |
| return tuple(_put_tensors_in_obj(v, tensors) for v in obj) |
| elif isinstance(obj, set): |
| return {_put_tensors_in_obj(v, tensors) for v in obj} |
| else: |
| return obj |
|
|